Measurement of the neutron radius of 208Pb through parity violation in electron scattering

We report the first measurement of the parity-violating asymmetry A(PV) in the elastic scattering of polarized electrons from 208Pb. A(PV) is sensitive to the radius of the neutron distribution (R(n)). The result A(PV)=0.656±0.060(stat)±0.014(syst) ppm corresponds to a difference between the radii of the neutron and proton distributions R(n)-R(p)=0.33(-0.18)(+0.16) fm and provides the first electroweak observation of the neutron skin which is expected in a heavy, neutron-rich nucleus.

Liver aldehyde oxidase and xanthine oxidase genetics in the mouse

A 'null' activity variant for the major liver isozyme of aldehyde oxidase (AOX-1) in adult male mice and an electrophoretically distinct, high activity variant of the second liver isozyme (AOX-2) were used to examine the segregation of the genetic loci encoding these enzymes (Aox-1 and Aox-2 respectively) in breeding studies. A single recombinant between these loci was observed among the 147 backcross progeny examined, which confirms a previous report (Holmes, 1979) for close linkage and genetic distinctness of the two loci. An activity variant for mouse liver xanthine oxidase (XOX) is also reported which behaved as though controlled by codominant alleles at a single locus (designated Xox-1). Genetic analyses showed that the Xox-1 locus segregated independently of the multiple-Aox loci.

Aldehyde oxidase and alcohol dehydrogenase genetics in the mouse. New alleles for the Aox-2 and Adh-3 loci

The genetic variability of one of the liver isozymes of aldehyde oxidase (AOX-B2 or AOX-2) and the stomach isozyme of alcohol dehydrogenase (ADH-C2) has been examined among strains of mice. Evidence is presented for a fourth allele of Aox-2 and a third allele of Adh-3. The hybrid allozyme pattern for mouse liver AOX was consistent with a dimeric subunit structure for this enzyme.

Alcohol dehydrogenase isozymes in the mouse: genetic regulation, allelic variation among inbred strains and sex differences of liver and kidney A2 isozyme activity

Genetic analysis of a proposed cis-acting temporal locus (Adh-3t), which regulates alcohol dehydrogenase C2 (ADH-C2) activity in mouse epididymis extracts, among F1 (ddN X BALB/c) X ddN male backcross progeny provided evidence for genetic distinctness between the structural (Adh-3) and temporal (Adh-3t) loci on chromosome 3. Genetic analysis also confirmed the close linkage of Adh-1 (encoding liver and kidney ADH-A2) and Adh-3 (encoding stomach ADH-C2) to within 0.3 centimorgans on the mouse genome. Evidence is presented for a proposed closely linked cis-acting temporal locus (designated Adh-lt) for the A2 isozyme (encoded by Adh-1) controlling the activity of this enzyme in mouse kidney extracts, but having no apparent affect on liver and intestine ADH-A2 activities. An extensive survey of the distribution of Adh-1, Adh-3 and Adh-3t alleles among 65 strains of mice is reported--with the exception of two Japanese strains (ddN and KF), linkage disequilibrium between Adh-3 and Adh-3t was observed. Sex differences in mouse liver and kidney ADH-A2 activities were observed, with male/female ratios of approximately 0.6 and 3 respectively for these tissue extracts.

Gene markers for alcohol-metabolizing enzymes among recombinant inbred strains of mice with differential behavioural responses towards alcohol

The genetic variability of alcohol dehydrogenase (C2 isozyme), aldehyde dehydrogenase (A2 isozyme) and aldehyde oxidase (A2 isozyme) has been examined among recombinant inbred strains of mice which have been previously studied concerning their differential behavioural responses towards alcohol. The results showed no correlation between biochemical phenotype for these loci and behavioural response.

Genetics and development of ocular oxidases in the mouse: evidence for a new locus (Eox-1) closely linked with the aldehyde oxidase loci on chromosome 1

Isoelectric focusing (IEF) and histochemical techniques were used to examine the genetics, postnatal development and biochemical properties of ocular oxidases (EOXs) among inbred strains of mice. The designation as EOX was made on a provisional basis, since the 'natural' substrate(s) for this enzyme have not been identified. Five major forms were resolved from adult animals, which exhibited high activity in murine lens and low activity in the cornea. An additional ocular oxidase was observed in neonatal animals. Genetic analyses demonstrated that one of these enzymes (EOX-1) is encoded by a locus (Eox-1) which is closely linked with, but distinct from, the aldehyde oxidase (Aox) gene complex on chromosome one of the mouse. These results support the proposal that ocular oxidases are distinct from the major liver AOXs in this organism.

Sorbitol dehydrogenase genetics in the mouse: a 'null' mutant in a 'European' C57BL strain

A 'null' activity variant phenotype for sorbitol dehydrogenase (SDH) was observed in C57BL/LiA mice and used to examine the genetics of this enzyme. Linkage studies of the locus (Sdh-1) with non-agouti (a) and a biochemical locus encoding liver L-alpha-hydroxyacid oxidase (Hao-1) demonstrated that it is coincident with or closely linked to the structural locus, previously localized on chromosome 2. Alcohol dehydrogenase (ADH) isozymes were also examined, since the liver A2 isozyme exhibited some activity as a sorbitol dehydrogenase on cellulose acetate zymograms. It is apparent that SDH activity is not 'essential' in this mouse strain.

Alcohol dehydrogenases and aldehyde dehydrogenases among inbred strains of mice: multiplicity, development, genetic studies and metabolic roles

Alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) are the major enzymes responsible for the metabolism of alcohols and aldehydes in the body. Both exist as a family of isozymes in mammals, and have been extensively studied in animal models, particularly among inbred strains of mice. Mouse ADH exists as at least three major classes, which are predominantly localized in liver (classes I and III), and in stomach/cornea (class IV). Mouse ALDH exhibits extensive multiplicity, several forms of which have been characterized, including ALDH1 (liver cytoplasmic/class 1 isozyme); ALDH2 (liver mitochondrial/class 2.); ALDH3 (stomach cytosolic/class 3); ALDH4 (liver microsomal/class 3); and ALDH5 (testis cytosolic/class 3). Biochemical, genetic and molecular genetic analyses have been performed on several of these enzymes, including studies on variant forms of ADH and ALDH. Distinct metabolic roles are proposed, based upon their tissue and subcellular distribution characteristics and the biochemical properties for these enzymes.

Recommended nomenclature for the vertebrate alcohol dehydrogenase gene family

The alcohol dehydrogenase (ADH) gene family encodes enzymes that metabolize a wide variety of substrates, including ethanol, retinol, other aliphatic alcohols, hydroxysteroids, and lipid peroxidation products. Studies on 19 vertebrate animals have identified ADH orthologs across several species, and this has now led to questions of how best to name ADH proteins and genes. Seven distinct classes of vertebrate ADH encoded by non-orthologous genes have been defined based upon sequence homology as well as unique catalytic properties or gene expression patterns. Each class of vertebrate ADH shares <70% sequence identity with other classes of ADH in the same species. Classes may be further divided into multiple closely related isoenzymes sharing >80% sequence identity such as the case for class I ADH where humans have three class I ADH genes, horses have two, and mice have only one. Presented here is a nomenclature that uses the widely accepted vertebrate ADH class system as its basis. It follows the guidelines of human and mouse gene nomenclature committees, which recommend coordinating names across species boundaries and eliminating Roman numerals and Greek symbols. We recommend that enzyme subunits be referred to by the symbol "ADH" (alcohol dehydrogenase) followed by an Arabic number denoting the class; i.e. ADH1 for class I ADH. For genes we recommend the italicized root symbol "ADH" for human and "Adh" for mouse, followed by the appropriate Arabic number for the class; i.e. ADH1 or Adh1 for class I ADH genes. For organisms where multiple species-specific isoenzymes exist within a class, we recommend adding a capital letter after the Arabic number; i.e. ADH1A, ADH1B, and ADH1C for human alpha, beta, and gamma class I ADHs, respectively. This nomenclature will accommodate newly discovered members of the vertebrate ADH family, and will facilitate functional and evolutionary studies.

Evolution of class I alcohol dehydrogenase genes in catarrhine primates: gene conversion, substitution rates, and gene regulation

The three class I alcohol dehydrogenases (ADHs) in humans comprise homo- and heterodimers of three subunits (alpha, beta, and gamma) with greater than 90% sequence identity. These are encoded by distinct genes (ADH1, ADH2, and ADH3, respectively) and are all expressed in the liver. In baboons, only the beta ADH subunit is expressed in liver. A second class I ADH is expressed in the kidney; we isolated, cloned, and sequenced the cDNA corresponding to this ADH and conclude that it is of the gamma ADH lineage. We also amplified and sequenced the 5' noncoding regions of all three class I baboon ADH genes and the rhesus monkey ADH1 gene and compared their nucleotide sequences with the corresponding human sequences. There is clear evidence that the evolution of these genes has been reticulate. At least three gene conversion events, affecting the coding and 3' noncoding regions of the genes, are inferred from compatibility and partition matrices and phylogenetic analysis of the sequences. Our estimation of the evolutionary history of these genes provides a framework for the investigation of relative substitution rates and functional variation among the sequences. Relative-rate tests, designed to account for the reticulate evolution of these genes, indicate no difference in substitution rate either between genes encoding different subunits or between human and Old World monkey lineages. The human and baboon gamma ADH sequences do not show clear differences at functionally important sites within the coding region, but they do differ at a number of sites in regions previously proposed to be regulatory sites for transcriptional control. This variation may explain the different patterns of gene expression in humans and baboons.

A genetic basis for corneal sensitivity to ultraviolet light among recombinant SWXJ inbred strains of mice

PURPOSE

To examine a possible genetic basis for corneal sensitivity to UV-B light exposure.

METHODS

To this end, adult male mice from the 14 SWXJ recombinant inbred albino strains (originating from SJL/J and SWR/J parental strains) were subjected to ultraviolet (UV) radiation exposure of 0.078 J/cm2 and photographed four days post-exposure, to assess corneal opacity and the possible correlation with corneal aldehyde dehydrogenase (ALDH) activity, alcohol dehydrogenase (ADH) activity and soluble protein content.

RESULTS

Those recombinant strains that exhibited the SWR/J strain phenotype of having low levels of ALDH and decreased soluble protein levels also exhibited greater levels of corneal clouding after UV-exposure than the other strains, which exhibited "normal" levels of both ALDH activity and soluble protein in the cornea.

CONCLUSIONS

These data support an hypothesis for a major role for ALDH in assisting the cornea to protect the eye against UV-induced tissue damage.

Human stomach class IV alcohol dehydrogenase: molecular genetic analysis

A partial human stomach alcohol dehydrogenase (ADH) encoding cDNA has been isolated, cloned, and sequenced, which contains 222 nucleotides encoding amino acid residues 227-299 of the ADH subunit. The amino acid sequence deduced from this cDNA was highly homologous with the rat stomach class IV ADH sequence recently reported (81.1% sequence identity). Homology with other human ADH classes was also observed: class I, 58.1% sequence identity; class II, 39.2% sequence identity; class III, 55.4% sequence identity; and class V, 50.0% sequence identity. These results support a proposal that the isolated cDNA encodes a partial sequence for human stomach class IV ADH. This sequence retains val294 for all other human ADH classes reported, as compared with an ala294 at this position reported for rat class IV ADH. This ala residue may contribute to the very high Km values with ethanol for the latter enzyme. In addition, three substitutions are reported for key residues in the coenzyme binding site: 251, gln/ser; 260, gly/asn; and 261, gly/asn, which may contribute to the weak coenzyme binding properties reported for human class IV ADH.

Differential corneal sensitivity to ultraviolet light among inbred strains of mice. Correlation of ultraviolet B sensitivity with aldehyde dehydrogenase deficiency

Adult male mice from four inbred albino strains (SJL/J, NZW/BL, BALB/c HeA, and SWR/J) were subjected to ultraviolet radiation (UVR) exposure (302 nm peak wavelength, intensity 398 microW/cm2) for 3.25 min and photographed 4 days postexposure to assess corneal clouding. Corneal extracts from control (unexposed) mice from each strain, were also monitored for aldehyde dehydrogenase (ALDH) and alcohol dehydrogenase (ADH) activity and soluble protein content. The SWR/J strain exhibited more extensive corneal clouding after UV exposure than did the other strains, and control SWR/J mice exhibited a low activity variant phenotype for the major ocular ALDH AHD-4, and decreased levels of soluble protein in corneal extracts. These data support earlier proposals for a major role for ALDH in assisting the cornea in protecting the eye against UVR-induced tissue damage.

Human corneal aldehyde dehydrogenase: purification, kinetic characterisation and phenotypic variation

Human corneal aldehyde dehydrogenase (designated ALDH3) was purified to homogeneity and characterised with respect to substrate specificity and inhibition by thiol reagents. The enzyme was present as a major soluble protein (5% of the total soluble protein) and was found to efficiently catalyse the oxidation of medium chain peroxidic aldehydes which may be found in the cornea. These findings are consistent with the proposal that ALDH3 plays a dual role in the absorption of UVR and in the oxidation of peroxidic aldehydes in the mammalian cornea. Disulfiram did not inhibit this enzyme under the conditions used in this study, however p-hydroxymercuribenzoate rapidly inactivated the enzyme. Analysis of the proteins of the cornea and surrounding tissue indicated that in both the cow and the human, changes in the nature and quantity of soluble proteins occurred. Phenotype variants of the ALDH3 were apparent in a small Australian population.

Purification and properties of murine corneal aldehyde dehydrogenase

Murine corneal aldehyde dehydrogenase has been purified to homogeneity and characterized with a range of aldehyde substrates at pH 7.4. The enzyme was a dimer with a subunit molecular weight of 59 KDa. and appears to prefer aldehyde products of lipid peroxidation as substrates. The enzyme constituted approximately 5% of the total soluble protein of mouse cornea. A dual role has been proposed for corneal aldehyde dehydrogenase in providing the eye with protection against UV-B light: by oxidizing aldehydes generated through light-induced lipid peroxidation; and by the direct absorption of UV-B light by the enzyme.

Ultraviolet light-induced pathology in the eye: associated changes in ocular aldehyde dehydrogenase and alcohol dehydrogenase activities

Adult male C57BL/6J inbred mice were subjected to ultraviolet radiation (UVR) exposure (302-nm peak wavelength; average intensity 282 microW/cm2) for 1 h and monitored for ocular aldehyde dehydrogenase (ALDH) and alcohol dehydrogenase (ADH) activity changes over a period of 25 days. Dramatic reductions in activities were observed by 4-6 days postexposure, resulting in enzyme levels of 15-16% of control animals. Major decreases in corneal enzyme levels were predominantly responsible for these changes. Ocular morphology was observed throughout using a photoslit-lamp biomicroscope, with maximum corneal clouding occurring at days 4-6. These data support earlier proposals for major roles for these corneal enzymes in assisting the cornea in protecting the eye against UVR-induced tissue damage.

Regional distribution of mammalian corneal aldehyde dehydrogenase and alcohol dehydrogenase

The regional distribution of mouse aldehyde dehydrogenase (ALDH) and alcohol dehydrogenase activities in mouse ocular tissues was examined using spectrophotometric and agarose-isoelectric focusing techniques. The results established that these enzymes are predominantly localized in the cornea. Biochemical and histochemical analyses of the localization of these enzymes in the corneas of common domestic mammals (pigs, sheep, and cattle) and in baboons revealed species differences, with high levels being reported in corneal epithelium (pigs and baboons) and endothelium (sheep and cattle). The presence of these enzymes in the corneal epithelium is consistent with their proposed catalytic role in the detoxification of ultraviolet (UV)-induced peroxidic aldehydes, and with the proposed role for corneal ALDH in UVB absorption.

A gastric alcohol dehydrogenase in the baboon: purification and properties of a 'high-Km' enzyme, consistent with a role in 'first pass' alcohol metabolism

The major isozyme of alcohol dehydrogenase in baboon stomach, ADH3, has been purified to homogeneity and characterized with a range of alcohol and aldehyde substrates. Using kcat/Km values as an indication of substrate efficacy, medium-chain length aliphatic alcohols and aldehydes were identified as the preferred substrates. ADH3 showed 'high-Km' properties with respect to ethanol, and is expected to significantly contribute to 'first-pass' metabolism of alcohol. The enzyme exhibited more than two orders of magnitude higher turnover of substrate than the baboon liver 'low-Km' ADH, and may play a role in the rapid metabolism of a wide range of ingested alcohols in the diet.

Biochemical genetics of alcohol dehydrogenase isozymes in the gray short-tailed opossum (Monodelphis domestica)

Polyacrylamide gel-isoelectric focusing (PAGE-IEF) methods were used to examine the multiplicity, tissue distribution, and biochemical genetics of alcohol dehydrogenase (ADH) isozymes among gray short-tailed opossums (Monodelphis domestica). Seven ADH isozymes were resolved and distinguished on the basis of their isoelectric points, tissue distributions, and substrate and inhibitor specificities. ADH1 and ADH2 exhibited Class I properties and were observed in liver (and intestine) extracts. ADH3, ADH4, and ADH5 showed "high-Km" (possibly Class IV) properties, with ADH3 and ADH4 exhibiting high activity in cornea, ear, stomach, and esophagus extracts. ADH6 and ADH7 exhibited Class III properties, including activities as formaldehyde dehydrogenases, with each showing different tissue distribution characteristics; ADH6 was widely distributed, and ADH7 was restricted to prostate extracts. An additional form of formaldehyde dehydrogenase (FDH) was observed, which was inactive with hexenol and ethanol as substrates. Isoelectric point variants were observed for ADH3 (three forms) and for ADH4 (two forms), and the inheritance of ADH3 was studied in 15 families of M. domestica. The data were consistent with codominant inheritance of two alleles (ADH3*A and ADH3*B) at a single autosomal locus (designated ADH3) and with a model involving a dimeric ADH isozyme: ADH3 (gamma 2 isozyme, forming three dimers designated gamma 1(2), gamma 1 gamma 2, and gamma 2(2) in heterozygous individuals).

Evidence for three genes encoding class-I alcohol dehydrogenase subunits in baboon and analysis of the 5' region of the gene encoding the ADH beta subunit

Five alcohol dehydrogenases (ADH; alcohol: NAD+ oxidoreductase; EC 1.1.1.1) have been identified in the baboon. All are homodimers of five distinct ADH subunits, with the two class-I ADH subunits being differentially expressed in the liver (the beta-subunit) and kidney. We have hybridized restriction-enzyme-digested baboon DNA to a 30-bp probe or a 337-bp DNA fragment, to reveal the presence of three genes encoding class-I ADH subunits in the baboon genome. This result was confirmed by the amplification of three different baboon ADH (bADH) nucleotide (nt) sequences, corresponding to exon 5 in the human gene encoding ADH beta (hADHB) from baboon DNA. Two of these sequences are identical to previously isolated liver and kidney cDNA nt sequences. These results are consistent with a phylogenetic analysis of the nt sequences of class-I hADH and bADH genes. Then, using primers based on the nt sequence of hADHB, we amplified a 336-bp DNA fragment, from genomic DNA, encoding the 5' region of the bADHB gene. In a 49-bp region of overlap, the nt sequence of this DNA fragment was identical to the sequence of a cDNA fragment amplified from baboon liver mRNA, whereas there were seven differences between this DNA fragment and the sequence of a cDNA amplified from baboon kidney mRNA. We used primer extension analysis to identify three adjacent transcriptional start points (tsp) for bADHB mRNA. Initiation of transcription at the most 5' bp leaves a 72-bp untranslated region. Examination of the sequence upstream from the tsp reveals a number of conserved putative regulatory sequence elements.

Aldehyde dehydrogenase (ALDH) isozymes in the gray short-tailed opossum (Monodelphis domestica): tissue and subcellular distribution and biochemical genetics of ALDH3

Polyacrylamide gel isoelectric focusing (PAGE-IEF), cellulose acetate electrophoresis, and histochemical techniques were used to examine the tissue and subcellular distribution, genetics and biochemical properties of aldehyde dehydrogenase (ALDH) isozymes in a didelphid marsupial, the gray short-tail opossum (Monodelphis domestica). At least 14 zones of activity were resolved by PAGE-IEF and divided into five isozyme groups and three ALDH classes, based upon comparisons with properties previously reported for human, baboon, rat, and mouse ALDHs. Opossum liver ALDHs were distributed among cytosol (ALDHs 1 and 5) and large granular (mitochondrial) fractions (ALDHs 2 and 5). Similarly, kidney ALDHs were distributed between the cytosol (ALDH5) and the mitochondrial fractions (ALDHs 2, 4, and 5), whereas a major isozyme (ALDH3), found in high activity in cornea, esophagus, ear pinna, tail, and stomach extracts, was localized predominantly in the cytosol fraction. Phenotypic variants of the latter enzyme were shown to be inherited in a normal Mendelian fashion, with two alleles at a single locus (ALDH3) showing codominant expression. The data provided evidence for genetic identity of corneal, ear pinna, tail, and stomach ALDH3 and supported biochemical evidence from other mammalian species that this enzyme has a dimeric subunit structure.

Postnatal development of mouse alcohol dehydrogenases: agarose isoelectric focusing analyses of the liver, kidney, stomach and ocular isozymes

The postnatal development of alcohol dehydrogenase (ADH) isozymes was studied in liver, kidney, stomach and eye tissues of C57BL/6J inbred male mice using agarose isoelectric focusing and histochemical methods. Development profiles were tissue specific, with adult patterns being attained by 30 days in the liver and stomach, and by 42 days in the kidneys. Ocular ADH-C2 increased in activity at the end of the first week, corresponding to the time of eye opening in the neonate.

Relationships between resistance to cross-linking agents and glutathione metabolism, aldehyde dehydrogenase isozymes and adenovirus replication in human tumour cell lines

In a panel of 10 human tumour cell lines with no prior exposure to drugs in vitro, resistance to cisplatin correlated with resistance to the nitrogen mustard derivatives Asta Z-7557 (mafosfamide, an activated form of cyclophosphamide), melphalan and chlorambucil. Simultaneous treatment with DL-buthionine-S,R-sulfoximine did not enhance the toxicity of cisplatin or Asta Z-7557, and no correlation was found between drug resistance and cellular levels of metallothioneins (as judged by sensitivity to cadmium chloride), glutathione (GSH), GSH reductase, GSH transferase, or gamma-glutamyltranspeptidase. The two cell lines most resistant to Asta Z-7557 expressed aldehyde dehydrogenase cytosolic isozyme 1, found also in normal ovary, but not isozyme 3. Treatment of resistant cells with cisplatin or Asta Z-7557 inhibited cellular DNA synthesis and replication of adenovirus 5 to a lesser extent than in sensitive cells. The virus could be directly inactivated by both drugs prior to infection, subsequent replication being inhibited to the same extent in sensitive and resistant cells. In contrast to Asta Z-7557 and other DNA damaging agents, cisplatin was much more toxic to adenovirus (D37 0.022-0.048 microM) than to cells (D37 0.25-2.5 microM). The adenovirus 5 mutant Ad5ts125 having a G----A substitution was even more sensitive to cisplatin (D37 7-8 nM) than wild type virus and another mutant. Cisplatin was detoxified less by sonicated resistant resistant cells than sensitive cells, as judged by inactivation of Ad5ts125 added to the reaction mixture. It can be inferred that (i) the major differences in cellular resistance to cisplatin and Asta Z-7557 in the present material did not involve enhanced DNA repair or protection by metallothioneins or GSH, but were associated with the ability to continue cellular and viral DNA synthesis during treatment, (ii) resistance was not associated with less template damage, and (iii) the adenovirus genome may be a suitable probe for predicting tumour resistance to cisplatin and for elucidating the DNA sequence dependence of cisplatin toxicity.

Bovine corneal aldehyde dehydrogenase: the major soluble corneal protein with a possible dual protective role for the eye

Bovine corneal aldehyde dehydrogenase was purified to homogeneity and characterized with aldehyde substrates at pH 7.4. The enzyme was a dimer with a subunit size of 65 kDa. Using kcat/Km values as an indication of substrate efficacy, aldehyde products of lipid peroxidation were recognized as the likely 'natural' substrates. Protein yields from enzyme purification, as well as electrophoretic analyses of crude and purified enzyme preparations, demonstrated that this enzyme is the major soluble protein in bovine cornea, and constitutes around 0.5% wet weight of tissue. A dual role in protecting the eye against UV-B light is proposed--oxidation of aldehydes generated by light induced lipid peroxidation, and the direct absorption of UV-B light by bovine corneal ALDH.

Genetics of alcohol dehydrogenase and aldehyde dehydrogenase from Monodelphis domestica cornea: further evidence for identity of corneal aldehyde dehydrogenase with a major soluble protein

A didelphid marsupial, the gray short-tailed opossum (Monodelphis domestica), was used as a model species to study the biochemical genetics of alcohol dehydrogenases (ADHs) and aldehyde dehydrogenase (ALDH) in corneal tissue. Isoelectric point variants of corneal ALDH (designated ALDH3) and a major soluble protein in corneal extracts were observed among eight families of animals used in studying the genetics of these proteins. Both phenotypes exhibited identical patterns following PAGE-IEF and were inherited in a normal Mendelian fashion, with two alleles at a single locus (ALDH3) showing codominant expression. The data provided evidence for genetic identity of corneal ALDH with this major soluble protein, and supported biochemical evidence, recently reported for purified bovine corneal ALDH, that this enzyme constitutes a major portion of soluble corneal protein (Abedinia et al. 1990). Isoelectric point variants for corneal ADH were also observed, with patterns for the two major forms (ADH3 and ADH4) and one minor form (ADH5) being consistent with the presence of two ADH subunits (designated gamma and delta), and variant phenotypes existing for the gamma subunit. The genetics of this enzyme was studied in the eight families, and the results were consistent with codominant expression of two alleles at a single locus (designated ADH3). It is relevant that a major detoxification function has been proposed for corneal ADH and ALDH, in the oxidoreduction of peroxidic aldehydes induced by available oxygen and UV-B light (Holmes & VandeBerg, 1986a). In addition, a direct role for corneal ALDH as a UV-B photoreceptor in this anterior eye tissue has also been proposed (Abedinia et al. 1990).

Cloning and sequencing of cDNA encoding baboon liver alcohol dehydrogenase: evidence for a common ancestral lineage with the human alcohol dehydrogenase beta subunit and for class I ADH gene duplications predating primate radiation

The baboon has at least five alcohol dehydrogenases (ADH; alcohol:NAD+ oxidoreductase, EC 1.1.1.1) and has distinct liver and kidney class I isozymes. A rat liver class I ADH partial cDNA was used to screen a baboon liver cDNA library. A cDNA clone was isolated and sequenced and found to contain the entire coding region for baboon liver ADH, 12 nucleotides of the 5' noncoding region, and 256 nucleotides of the 3' noncoding region. The amino acid sequence deduced from this cDNA most closely resembles that of human liver ADH beta subunit (ADH-beta): 363 of 374 residues were identical. This suggested that baboon liver class I ADH is of the same ancestral lineage as the human ADH-beta. In contrast to human liver, only a single ADH-beta transcript is observed in baboon liver. A comparison of human and baboon ADH 3' noncoding regions suggests that a single nucleotide change in a polyadenylylation signal consensus sequence may, in part, be responsible for the generation of ADH-beta transcripts with variable-length 3' ends in human liver. A nucleotide substitution rate of 0.5 x 10(-9) substitutions per site per year for primate class I ADH genes was deduced from the data, which suggests that the alpha-beta gamma separation of human ADH genes occurred about 60 million years ago, and that primate class I ADH gene duplications predated primate radiation.

Purification and properties of mouse stomach aldehyde dehydrogenase. Evidence for a role in the oxidation of peroxidic and aromatic aldehydes

The major isozyme of aldehyde dehydrogenase in mouse stomach, AHD-4, has been purified to homogeneity and characterized with a range of aldehyde substrates at pH 7.4. The enzyme was a dimer with a subunit size of 65 kDa. Using V/Km values as an indication of substrate efficacy, aromatic aldehydes were the preferred substrates. The enzyme used either NAD+ or NADP+ as cofactor, but showed a preference for NAD+. AHD-4 showed 'high-Km' properties with respect to acetaldehyde, but differed from the 'high-Km' liver mitochondrial enzyme (AHD-1), in that it was not a semialdehyde dehydrogenase. The enzyme was significantly active towards the peroxidic aldehyde, 4-hydroxynonenal, and may play a role in vivo in the detoxification of aromatic aldehydes and the aldehyde products of lipid peroxidation.

Isoelectric focusing studies of aldehyde dehydrogenases, alcohol dehydrogenases and oxidases from mammalian anterior eye tissues

1. Isoelectric focusing (IEF) and zymogram methods were used to examine the tissue distribution, multiplicity and substrate specificities of alcohol dehydrogenases (ADHs), aldehyde dehydrogenases (ALDHs) and ocular oxidases (EOXs) from mammalian anterior eye tissues. 2. Baboon, cattle, pig and sheep corneal extracts exhibited high ALDH activities; the corneal ALDHs were distinct from the major liver ALDHs and distinguished by their preference for medium-chain aldehydes. 3. Baboon and pig corneal extracts also showed high ADH activities, by comparison with ovine and bovine samples. Moreover, the ADHs were distinct from the major liver isozymes in pI value and substrate specificity. 4. Mammalian lens extracts exhibited significant ALDH activity of a form corresponding to the major liver cytosolic isozyme. Minor activity of the corneal enzyme was also observed in some species. 5. Lens ADH phenotypes were species-specific, and consisted of either Class II activity (baboon and sheep), Class III ADH activity (pig), or activities of both ADH classes (cattle). 6. Lens extracts also exhibited a complex pattern of ocular oxidase (EOX) activities following IEF. 7. A role in peroxidatic aldehyde detoxification is proposed for these enzymes in anterior eye tissues.

Genetics of ocular NAD+-dependent alcohol dehydrogenase and aldehyde dehydrogenase in the mouse: evidence for genetic identity with stomach isozymes and localization of Ahd-4 on chromosome 11 near trembler

Electrophoretic and activity variation of the stomach and ocular isozyme of aldehyde dehydrogenase (designated AHD-4) was observed between C57BL/6J and SWR/J inbred strains of mice. The phenotypes were inherited in a normal mendelian fashion, with two alleles at a single locus (Ahd-4) showing codominant expression. The alleles assorted independently of those at Adh-3 [encoding the stomach and ocular isozyme of alcohol dehydrogenase (ADH-C2)] on chromosome 3. Three chromosome 11 markers, hemoglobin alpha-chain (Hba), trembler (Tr), and rex (Re), were used in backcross analyses which established that Ahd-4 is closely linked to trembler. The distribution patterns for stomach and ocular AHD-4 phenotypes were examined among SWXL recombinant inbred mice, and those for stomach and ocular ADH-C2 among BXD recombinant inbred strains. The data provided evidence for the genetic identity of stomach and ocular ADH-C2 and of stomach and ocular AHD-4.

Developmental changes in aldehyde dehydrogenases from mouse tissues

The postnatal development of aldehyde dehydrogenase (AHD) isozymes from C57BL/6J mouse tissues was examined using agarose-IEF zymogram methods. Mitochondrial isozymes (AHD-1 and AHD-5) were present throughout, increasing to high levels in liver, kidney and stomach by weaning (3 weeks). These activities remained high subsequently, except for kidney AHD-5, which decreased significantly after week 4. The appearance of the cytosolic isozymes was tissue specific and time dependent: liver AHD-2 was undetected until day 21, and increased subsequently; stomach AHD-4 was first observed at day 5, increasing to adult levels by day 21; AHD-6 was active in neonatal kidney and stomach extracts, but was undetected after day 8; and AHD-7 was observed in liver and kidney extracts from day 16. These results supported previous proposals for multiple genes encoding aldehyde dehydrogenases in the mouse, based upon the distinct developmental profiles for the liver, kidney and stomach isozymes.

Alcohol dehydrogenase isozymes in baboons: tissue distribution, catalytic properties, and variant phenotypes in liver, kidney, stomach, and testis

Isoelectric focusing and cellulose acetate electrophoresis were used to examine the multiplicity, tissue distribution, and variability of alcohol dehydrogenase (ADH) among baboons, a primate species used as a model for research on alcohol metabolism and alcohol-induced liver pathology. Five major ADH isozymes were resolved and distinguished on the basis of their isoelectric points, tissue distributions, relative activities with alcohol substrates, and sensitivities to inhibition with 4-methyl pyrazole. ADH-1 and ADH-2 exhibited class I kinetic properties and were observed in high activity in kidney and liver extracts, respectively. ADH-3 showed class II kinetic properties, exhibiting high activity in stomach extracts, and was widely distributed in extracts of other baboon tissues, including kidney, esophagus, heart, testis, brain, and male sex accessory tissues. ADH-4 also showed class II ADH properties but was found only in liver (similar to human "pi-ADH"). ADH-5 exhibited class III ADH kinetic properties, being inactive with ethanol up to 0.5 M (similar to human "chi-ADH") and was distributed widely in baboon tissue extracts. Major activity variation was observed for liver ADH-4 between different animals. An electrophoretic variant for ADH-3 was observed for the enzyme in stomach, kidney, and testis extracts, and activity variation existed for this isozyme in kidney extracts. It is apparent that baboon ADH shares a number of features with the human ADH phenotype; however, several species-specific differences were observed, particularly for the liver and kidney class I isozymes and for stomach ADH.

Ocular NAD-dependent alcohol dehydrogenase and aldehyde dehydrogenase in the baboon

Isoelectric focusing (IEF) techniques and spectrophotometric analyses were used to examine the distribution and properties of alcohol dehydrogenase (ADH) and aldehyde dehydrogenase (ALDH) isozymes in ocular tissue of olive and yellow baboons. Cornea extracts exhibited very high specific activities of the 'stomach-specific' ADH and ALDH isozymes (designated ADH-3 and ALDH-III respectively), and were devoid of the major liver and kidney isozymes. Lens extracts exhibited lower activities of ADH-3 and ALDH-III, and also showed significant activity of ALDH-II (the major liver cytosolic isozyme) and a group of 'lens-specific' ALDHs of low isoelectric point. Extracts of baboon retina also exhibited ADH-3 and ALDH-III activities, together with activities of the major liver cytosolic (ALDH-II) and mitochondrial (ALDH-I) isozymes of ALDH; and ADH-5 (or chi-ADH) activity. Evidence was obtained for individual variation of ALDH-III activity in the lens. An electrophoretic variant for ADH-3 indicated genetic identity of the major stomach and ocular ADH isozyme. The catalytic properties of the high specific activity corneal ADH and ALDH isozymes indicated a role in the detoxification of lipid peroxidation by-products.

Genetic marker patterns and endogenous mammary tumor virus genes in inbred mouse strains of Japan

In order to establish the genetic relatedness of the inbred mouse strains kept in Nara, genetic marker patterns were determined in conjunction with a study on endogenous mammary tumor viral genes in these strains. Isoenzyme patterns combined with patterns of other genetic markers, show that the unrelatedness between various inbred strains of the dd stock is as high or even higher as between strains of known different origin and geneology. Based on endogenous viral gene patterns the dd stock derived mice can be subdivided into three group, DDD, DDN, DDO, KF and DD/Tbr. The DD/Tbr and its foster-nursed substrain (DD/Tbrf) have the lowest number of endogenous viral genes, i.e. two, while the other strains carry 4-6 such genes. The SLN and SHN strains, derived from a Swiss stock, have a similar pattern of viral genes different that of all other strains studied, also strains of Swiss origin from other sources, such as the NFS and the GR.

Biochemical genetic variants in mice selectively bred for sensitivity or resistance to ethanol-induced sedation

The distribution of biochemical genetic variants was examined among eight inbred strains of mice, which served as contributors to a heterogeneous stock of mice (HS), and in short-sleep (SS) and long-sleep (LS) mice, selectively bred from the HS stock for differential ethanol sensitivity. Fifteen loci for enzymes of alcohol and aldehyde metabolism, as well as 12 other biochemical loci, were investigated. Thirteen of these loci exhibited allelic variation between strains, of which six were separately fixed in the SS and LS mice. Comparisons of genetic similarity coefficients, based upon the distributions of allelic variants for the loci examined, with behavioural sensitivities (sleep-time) to an acute dose of ethanol for the inbred and selected strains of mice, indicated no correlations between these data. This suggests that this collective group of loci are not useful indicators of the genes selectively bred in the SS and LS strains, which are responsible for the differential sensitivities to acute doses of ethanol.

Aldehyde dehydrogenases, aldehyde oxidase and xanthine oxidase from baboon tissues: phenotypic variability and subcellular distribution in liver and brain

Isoelectric focusing (IEF) and cellulose acetate electrophoresis were used to examine the multiplicity and distribution of aldehyde dehydrogenases (ALDHs), aldehyde oxidase (AOX) and xanthine oxidase (XOX) from tissues of olive and yellow baboons. Five ALDHs were resolved and distinguished on the basis of their differential tissue and subcellular distribution or substrate specificity. Some ALDHs exhibited multiple activity zones. Baboon liver ALDHs were differentially distributed in cytosol (ALDHs II, III and V) and large granular (mitochondrial) fractions (ALDHs I and IV). The major liver ALDHs (I and II) were also broadly distributed in other tissues, as was the major stomach enzyme (ALDH-III). Three brain ALDHs were resolved, which were also differentially distributed between large granular (mitochondrial) (ALDHs I and IV) and cytosolic (ALDH-III) fractions. Electrophoretic variability between individuals was observed for the major liver mitochondrial isozyme (ALDH-I), the major stomach isozyme (ALDH-III) and the minor liver isozymes (ALDHs IV and V). Single forms of AOX and XOX were found in baboon tissue extracts, with the highest activities in liver (AOX) and intestine extracts (XOX). Both oxidases were predominantly localized in the liver soluble fraction.

Liver cytosolic aldehyde dehydrogenases from "alcohol-drinking" and "alcohol-avoiding" mouse strains: purification and molecular properties

Liver cytosolic aldehyde dehydrogenases (AHD-2) have been isolated in a highly purified state from "alcohol-drinking" (C57BL/6J) and "alcohol-avoiding" (DBA/2J) strains of mice. The purified enzymes were resolved into three major and one minor form of activity by isoelectric focusing (IEF) techniques and showed similar zymogram patterns. The enzymes had identical subunit sizes on SDS-polyacrylamide gels: 53,000. Gel exclusion chromatography, using Ultrogel AcA34, indicated that the enzymes were dimers. The enzymes exhibited biphasic kinetic characteristics and were readily distinguished from each other. The purified forms of AHD-2 from C57BL/6J and DBA/2J mice exhibited two apparent Km values in each case: 10 microM/100 microM and 30 microM/330 microM respectively. AHD-2 exhibited a broad pH optimum in the range 7.0-9.0 and was very sensitive towards disulphuram inhibition, with 50% inhibition occurring at 0.17 microM. The kinetic results support proposals that AHD-2 may be the primary enzyme for oxidizing acetaldehyde during ethanol oxidation in vivo.

Genetic variants of enzymes of alcohol and aldehyde metabolism

The distribution of genetic variants (or gene markers) for alcohol dehydrogenase, aldehyde dehydrogenase, aldehyde oxidase, and aldehyde reductase isozymes has been examined among 12 inbred strains of mice. Electrophoretic variants are described for the major liver and stomach alcohol dehydrogenase isozymes (ADH-A2 and C2); liver, kidney, and stomach aldehyde dehydrogenase isozymes (AHD-1; AHD-2; AHD-4); a liver-specific aldehyde reductase (AHR-A2); and a liver aldehyde oxidase isozyme (AOX-2). Genetically determined activity variants were observed for a testis-specific aldehyde dehydrogenase (AHD-6); liver and kidney aldehyde reductase isozymes (AHR-3 and AHR-4); and the major liver AOX isozyme (AOX-1). These variants may serve as useful gene markers in alcohol research involving animal model studies with inbred strains in mice.

Interferon-induced guanylate-binding proteins: mapping of the murine Gbp-1 locus to chromosome 3

GBP-1 is the predominant species of a family of guanylate-binding proteins synthesized in mouse cells in response to interferons (IFNs) alpha, beta, or gamma. IFN inducibility of this 65,000-Da protein is controlled by alleles at a single autosomal locus, Gbp-1, with allele a encoding inducibility and allele b noninducibility. Here, we present evidence suggesting that both alleles occur in outbred populations of wild mice. Using recombinant inbred strains and classical linkage analysis of offspring of two-point and three-point backcrosses we demonstrate that Gbp-1 is linked to Adh-3 (encoding alcohol dehydrogenase C2) and VaJ (varitintwaddler-Jackson) located on the distal part of chromosome 3. The relevant recombination frequencies (RFs) (+/- SE) were 3.5 (+/- 1.1) and 11.7 (+/- 2.8)%, respectively. We further show that strain B6.C-H-23c/By(HW 53), congenic for a small segment of chromosome 3, carries the BALB/c alleles at both the Gbp-1 and the Adh-3 locus and not the alleles of the B6 background strain confirming the chromosomal location and close linkage of the two loci.

Aldehyde reductase isozymes in the mouse: evidence for two new loci and localization of Ahr-3 on chromosome 7

Evidence is presented for two new forms of mouse liver and kidney aldehyde reductase activity (designated AHR-3 and AHR-4) resolved using cellulose acetate electrophoresis zymogram techniques and stained by glyceraldehyde and NADPH as substrate and coenzyme, respectively. Activity variants were observed for those isozymes among inbred strains of mice and used in a genetic analyses to support a proposal for two new genetic loci (Ahr-3 and Ah-4) which control the activity phenotype for these isozymes. Segregation analysis indicated that these loci are separately localized on the mouse genome, with Ahr-3 positioned on the distal end of chromosome 7. Liver AHR-2 (or hexonate dehydrogenase) exhibited no detectable phenotypic variation among the 44 inbred strains of mice examined. The AHR-3 and AHR-4 isozymes were readily distinguished from AHR-1 [or aldehyde reductase A2, described previously by Duley and Holmes (Biochem. Genet. 20:1067, 1982)], hexonate dehydrogenase (AHR-2), and alcohol dehydrogenase A2 in terms of their differential substrate, coenzyme, and inhibitor specificities.

Analysis of human alcohol- and aldehyde-metabolizing isozymes by electrophoresis and isoelectric focusing

Isoelectric focusing and electrophoresis were used to identify the various isozymes of alcohol dehydrogenase (ADH), aldehyde dehydrogenase (ALDH), aldehyde oxidase (AOX), and xanthine oxidase (XOX). ADH types I, II, and III were located primarily in the cytosol fraction of liver, but some activity was found also in the small granule fraction. The ALDH-I and -IV isozymes were found in the large granule fraction, while ALDH-II and -III were present in the cytosol and ALDH-V in the small granule fraction. AOX and XOX each appeared as a single cytosolic form with some small granule activity. The tissue distribution of these isozymes is presented and the physiological role of each enzyme is discussed.

Biochemical genetics of aldehyde dehydrogenase isozymes in the mouse: evidence for stomach- and testis-specific isozymes

Electrophoretic and activity variants have been observed for stomach and testis aldehyde dehydrogenases, respectively, among inbred strains of the house mouse (Mus musculus). Genetic evidence was obtained for two new loci encoding these isozymes (designated Ahd-4 and Ahd-6, respectively, for the stomach and testis isozymes) which segregated independently of a number of mouse gene markers, including Ahd-1 (encoding mitochondrial aldehyde dehydrogenase) on chromosome 4, ep (pale ears), a marker for chromosome 19, on which Ahd-2 (encoding liver cytosolic aldehyde dehydrogenase) has been previously localized, and Adh-3 (encoding the stomach-specific isozyme of alcohol dehydrogenase) on chromosome 3. Recombination studies have indicated, however, that Ahd-4 and Ahd-6 are distinct but closely linked loci on the mouse genome. An extensive survey of the distribution of Ahd-1, Ahd-2, Ahd-4, and Ahd-6 alleles among 56 strains of mice is reported. No variants have been observed, so far, for the microsomal (AHD-3) and mitochondrial/cytosolic (AHD-5) isozymes previously described. This study, in combination with previous investigations on mouse aldehyde dehydrogenases, provides evidence for six genetic loci for this enzyme.

Mouse mitochondrial aldehyde dehydrogenase isozymes: purification and molecular properties

Aldehyde dehydrogenase isozymes (AHD-1 and AHD-5) have been isolated in a highly purified state from extracts of mouse liver mitochondria. The enzymes have distinct subunit sizes, as determined by SDS/polyacrylamide gel electrophoresis: AHD-1, 63,000; AHD-5, 49,000. Gel exclusion chromatography, using sephadex G-200, indicated that both isozymes are dimers, although AHD-1 may also exist as a monomeric form as well. The enzymes exhibited widely divergent kinetic characteristics. The purified allelic forms of AHD-1, AHD-1A (C57BL/6J mice) and AHD-1B (CBA/H mice), exhibited high Km values with acetaldehyde as substrate, 1.4 mM and 0.78 mM respectively, whereas AHD-5 exhibited a low Km value with acetaldehyde of 0.2 microM. In addition, the isozymes exhibited distinct pH optima for catalysis (AHD-1, pH range 6.5-7.5; AHD-5, pH range 8.5-10.0), and were differentially sensitive towards disulphuram inhibition, with 50% inhibition occurring 13 and 0.1 microM for the AHD-1 and AHD-5 isozyme respectively. Based upon the kinetic characteristics, it is suggested that AHD-5 may be the primary enzyme for oxidizing mitochondrial acetaldehyde during ethanol oxidation in vivo.

Application of the reverse dept polarization-transfer pulse sequence to monitor in vitro and in vivo metabolism of 13C-ethanol by 1H-NMR spectroscopy

Using the reverse 13C----1H DEPT polarization-transfer pulse sequence the metabolism of 13C ethanol in vitro and in vivo has been monitored by 1H-NMR spectroscopy. Using yeast alcohol dehydrogenase, acetaldehyde, the hydrated form of acetaldehyde and acetate were identified as metabolites of [2-13C]-ethanol. The ratio of hydrated to free acetaldehyde was dependent upon the protein concentration of the reaction mixture. Binding of acetaldehyde in an irreversible Schiffs base resulted in optimal enzyme activity. Hepatocytes from rats fasted for 20 h, metabolised [1-13C] and [2-13C]ethanol in a linear fashion, but no [13C]acetaldehyde was detected. Metabolic integrity of the hepatocytes was confirmed with [2-13C]acetate. The addition of disulfiram (50 micron) to hepatocyte suspensions which had been incubated with [1-13C]ethanol, resulted in the resynthesis of [13C]ethanol. The amount of [13C]ethanol resynthesized under these conditions represents intracellular acetaldehyde whose concentration was in the range of 400-800 mumol/g wet weight of hepatocytes when 50 mM ethanol had been originally incubated with the hepatocyte suspension. These studies show how NMR-polarization transfer pulse sequences can be used to monitor the metabolism of 13C-ethanol in vivo, and provide a unique tool to measure in vivo concentrations of acetaldehyde. The studies also suggest that cytoplasmic aldehyde dehydrogenase may play a major role in hepatic ethanol metabolism.